/*
 *
 *    Copyright (c) 2022 Project CHIP Authors
 *
 *    Licensed under the Apache License, Version 2.0 (the "License");
 *    you may not use this file except in compliance with the License.
 *    You may obtain a copy of the License at
 *
 *        http://www.apache.org/licenses/LICENSE-2.0
 *
 *    Unless required by applicable law or agreed to in writing, software
 *    distributed under the License is distributed on an "AS IS" BASIS,
 *    WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 *    See the License for the specific language governing permissions and
 *    limitations under the License.
 */

// THIS FILE IS GENERATED BY ZAP
// This file is generated from clusters-Structs.ipp.zapt

#include <clusters/DeviceEnergyManagement/Structs.h>

#include <app/data-model/StructDecodeIterator.h>
#include <app/data-model/WrappedStructEncoder.h>

namespace chip
{
namespace app
{
	namespace Clusters
	{
		namespace DeviceEnergyManagement
		{
			namespace Structs
			{

				namespace CostStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kCostType), costType);
						encoder.Encode(to_underlying(Fields::kValue), value);
						encoder.Encode(to_underlying(Fields::kDecimalPoints), decimalPoints);
						encoder.Encode(to_underlying(Fields::kCurrency), currency);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kCostType)) {
								err = DataModel::Decode(reader, costType);
							} else if (__context_tag == to_underlying(Fields::kValue)) {
								err = DataModel::Decode(reader, value);
							} else if (__context_tag ==
								   to_underlying(Fields::kDecimalPoints)) {
								err = DataModel::Decode(reader, decimalPoints);
							} else if (__context_tag == to_underlying(Fields::kCurrency)) {
								err = DataModel::Decode(reader, currency);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace CostStruct

				namespace PowerAdjustStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kMinPower), minPower);
						encoder.Encode(to_underlying(Fields::kMaxPower), maxPower);
						encoder.Encode(to_underlying(Fields::kMinDuration), minDuration);
						encoder.Encode(to_underlying(Fields::kMaxDuration), maxDuration);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kMinPower)) {
								err = DataModel::Decode(reader, minPower);
							} else if (__context_tag == to_underlying(Fields::kMaxPower)) {
								err = DataModel::Decode(reader, maxPower);
							} else if (__context_tag ==
								   to_underlying(Fields::kMinDuration)) {
								err = DataModel::Decode(reader, minDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaxDuration)) {
								err = DataModel::Decode(reader, maxDuration);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace PowerAdjustStruct

				namespace PowerAdjustCapabilityStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kPowerAdjustCapability),
							       powerAdjustCapability);
						encoder.Encode(to_underlying(Fields::kCause), cause);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag ==
							    to_underlying(Fields::kPowerAdjustCapability)) {
								err = DataModel::Decode(reader, powerAdjustCapability);
							} else if (__context_tag == to_underlying(Fields::kCause)) {
								err = DataModel::Decode(reader, cause);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace PowerAdjustCapabilityStruct

				namespace SlotStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kMinDuration), minDuration);
						encoder.Encode(to_underlying(Fields::kMaxDuration), maxDuration);
						encoder.Encode(to_underlying(Fields::kDefaultDuration),
							       defaultDuration);
						encoder.Encode(to_underlying(Fields::kElapsedSlotTime),
							       elapsedSlotTime);
						encoder.Encode(to_underlying(Fields::kRemainingSlotTime),
							       remainingSlotTime);
						encoder.Encode(to_underlying(Fields::kSlotIsPausable), slotIsPausable);
						encoder.Encode(to_underlying(Fields::kMinPauseDuration),
							       minPauseDuration);
						encoder.Encode(to_underlying(Fields::kMaxPauseDuration),
							       maxPauseDuration);
						encoder.Encode(to_underlying(Fields::kManufacturerESAState),
							       manufacturerESAState);
						encoder.Encode(to_underlying(Fields::kNominalPower), nominalPower);
						encoder.Encode(to_underlying(Fields::kMinPower), minPower);
						encoder.Encode(to_underlying(Fields::kMaxPower), maxPower);
						encoder.Encode(to_underlying(Fields::kNominalEnergy), nominalEnergy);
						encoder.Encode(to_underlying(Fields::kCosts), costs);
						encoder.Encode(to_underlying(Fields::kMinPowerAdjustment),
							       minPowerAdjustment);
						encoder.Encode(to_underlying(Fields::kMaxPowerAdjustment),
							       maxPowerAdjustment);
						encoder.Encode(to_underlying(Fields::kMinDurationAdjustment),
							       minDurationAdjustment);
						encoder.Encode(to_underlying(Fields::kMaxDurationAdjustment),
							       maxDurationAdjustment);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kMinDuration)) {
								err = DataModel::Decode(reader, minDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaxDuration)) {
								err = DataModel::Decode(reader, maxDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kDefaultDuration)) {
								err = DataModel::Decode(reader, defaultDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kElapsedSlotTime)) {
								err = DataModel::Decode(reader, elapsedSlotTime);
							} else if (__context_tag ==
								   to_underlying(Fields::kRemainingSlotTime)) {
								err = DataModel::Decode(reader, remainingSlotTime);
							} else if (__context_tag ==
								   to_underlying(Fields::kSlotIsPausable)) {
								err = DataModel::Decode(reader, slotIsPausable);
							} else if (__context_tag ==
								   to_underlying(Fields::kMinPauseDuration)) {
								err = DataModel::Decode(reader, minPauseDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaxPauseDuration)) {
								err = DataModel::Decode(reader, maxPauseDuration);
							} else if (__context_tag ==
								   to_underlying(Fields::kManufacturerESAState)) {
								err = DataModel::Decode(reader, manufacturerESAState);
							} else if (__context_tag ==
								   to_underlying(Fields::kNominalPower)) {
								err = DataModel::Decode(reader, nominalPower);
							} else if (__context_tag == to_underlying(Fields::kMinPower)) {
								err = DataModel::Decode(reader, minPower);
							} else if (__context_tag == to_underlying(Fields::kMaxPower)) {
								err = DataModel::Decode(reader, maxPower);
							} else if (__context_tag ==
								   to_underlying(Fields::kNominalEnergy)) {
								err = DataModel::Decode(reader, nominalEnergy);
							} else if (__context_tag == to_underlying(Fields::kCosts)) {
								err = DataModel::Decode(reader, costs);
							} else if (__context_tag ==
								   to_underlying(Fields::kMinPowerAdjustment)) {
								err = DataModel::Decode(reader, minPowerAdjustment);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaxPowerAdjustment)) {
								err = DataModel::Decode(reader, maxPowerAdjustment);
							} else if (__context_tag ==
								   to_underlying(Fields::kMinDurationAdjustment)) {
								err = DataModel::Decode(reader, minDurationAdjustment);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaxDurationAdjustment)) {
								err = DataModel::Decode(reader, maxDurationAdjustment);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace SlotStruct

				namespace ForecastStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kForecastID), forecastID);
						encoder.Encode(to_underlying(Fields::kActiveSlotNumber),
							       activeSlotNumber);
						encoder.Encode(to_underlying(Fields::kStartTime), startTime);
						encoder.Encode(to_underlying(Fields::kEndTime), endTime);
						encoder.Encode(to_underlying(Fields::kEarliestStartTime),
							       earliestStartTime);
						encoder.Encode(to_underlying(Fields::kLatestEndTime), latestEndTime);
						encoder.Encode(to_underlying(Fields::kIsPausable), isPausable);
						encoder.Encode(to_underlying(Fields::kSlots), slots);
						encoder.Encode(to_underlying(Fields::kForecastUpdateReason),
							       forecastUpdateReason);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kForecastID)) {
								err = DataModel::Decode(reader, forecastID);
							} else if (__context_tag ==
								   to_underlying(Fields::kActiveSlotNumber)) {
								err = DataModel::Decode(reader, activeSlotNumber);
							} else if (__context_tag == to_underlying(Fields::kStartTime)) {
								err = DataModel::Decode(reader, startTime);
							} else if (__context_tag == to_underlying(Fields::kEndTime)) {
								err = DataModel::Decode(reader, endTime);
							} else if (__context_tag ==
								   to_underlying(Fields::kEarliestStartTime)) {
								err = DataModel::Decode(reader, earliestStartTime);
							} else if (__context_tag ==
								   to_underlying(Fields::kLatestEndTime)) {
								err = DataModel::Decode(reader, latestEndTime);
							} else if (__context_tag ==
								   to_underlying(Fields::kIsPausable)) {
								err = DataModel::Decode(reader, isPausable);
							} else if (__context_tag == to_underlying(Fields::kSlots)) {
								err = DataModel::Decode(reader, slots);
							} else if (__context_tag ==
								   to_underlying(Fields::kForecastUpdateReason)) {
								err = DataModel::Decode(reader, forecastUpdateReason);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace ForecastStruct

				namespace ConstraintsStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kStartTime), startTime);
						encoder.Encode(to_underlying(Fields::kDuration), duration);
						encoder.Encode(to_underlying(Fields::kNominalPower), nominalPower);
						encoder.Encode(to_underlying(Fields::kMaximumEnergy), maximumEnergy);
						encoder.Encode(to_underlying(Fields::kLoadControl), loadControl);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kStartTime)) {
								err = DataModel::Decode(reader, startTime);
							} else if (__context_tag == to_underlying(Fields::kDuration)) {
								err = DataModel::Decode(reader, duration);
							} else if (__context_tag ==
								   to_underlying(Fields::kNominalPower)) {
								err = DataModel::Decode(reader, nominalPower);
							} else if (__context_tag ==
								   to_underlying(Fields::kMaximumEnergy)) {
								err = DataModel::Decode(reader, maximumEnergy);
							} else if (__context_tag ==
								   to_underlying(Fields::kLoadControl)) {
								err = DataModel::Decode(reader, loadControl);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace ConstraintsStruct

				namespace SlotAdjustmentStruct
				{
					CHIP_ERROR Type::Encode(TLV::TLVWriter &aWriter, TLV::Tag aTag) const
					{
						DataModel::WrappedStructEncoder encoder{ aWriter, aTag };
						encoder.Encode(to_underlying(Fields::kSlotIndex), slotIndex);
						encoder.Encode(to_underlying(Fields::kNominalPower), nominalPower);
						encoder.Encode(to_underlying(Fields::kDuration), duration);
						return encoder.Finalize();
					}

					CHIP_ERROR DecodableType::Decode(TLV::TLVReader &reader)
					{
						detail::StructDecodeIterator __iterator(reader);
						while (true) {
							uint8_t __context_tag = 0;
							CHIP_ERROR err = __iterator.Next(__context_tag);
							VerifyOrReturnError(err != CHIP_ERROR_END_OF_TLV,
									    CHIP_NO_ERROR);
							ReturnErrorOnFailure(err);

							if (__context_tag == to_underlying(Fields::kSlotIndex)) {
								err = DataModel::Decode(reader, slotIndex);
							} else if (__context_tag ==
								   to_underlying(Fields::kNominalPower)) {
								err = DataModel::Decode(reader, nominalPower);
							} else if (__context_tag == to_underlying(Fields::kDuration)) {
								err = DataModel::Decode(reader, duration);
							}

							ReturnErrorOnFailure(err);
						}
					}

				} // namespace SlotAdjustmentStruct
			} // namespace Structs
		} // namespace DeviceEnergyManagement
	} // namespace Clusters
} // namespace app
} // namespace chip
